JPH05204652A - Method of determining heritage and propagation of object attribute value and data processing system - Google Patents

Abstract

PURPOSE: To provide a method for expanding the propagation of an object attribute value between objects of a data processing system. CONSTITUTION: A target object 28 in an object layer 24 is discriminated according to a user's choice. The last attribute value of the target object 28 is displayed on a display device next. When the user choice is made, a new object attribute value is generated for the target object 28. A propagation group for the new object attribute value is formed according to the user specification of a relative factor and the new attribute value is applied to all the objects in the relative group.

Description

Detailed Description of the Invention

[0001]

FIELD OF THE INVENTION The present invention relates generally to methods for propagating object attribute values between objects in a data processing system, and in particular for extending access and changing object attribute values between object groups. Regarding options. More particularly, the present invention relates to a method of defining propagation groups for object attribute values without being limited by object rank or predefined object relationships.

[0002]

2. Description of the Related Art In data processing, the term "object" is a generic term for data referenced by a single name. Objects are identified to computers and users by their names. Objects have "attributes" that are related to computer operations. At the most basic level, names are attributes of all objects. The specific name for the object is the attribute value. An example of an object is a word processing document. As will be appreciated by those skilled in the art, word processing documents are named,
It has a font, line spacing definition, and background color. These are attributes, and these particular manifestations are object attribute values.

Objects of the "object type" are associated within a data processing system by attributes that define the object's purpose. Each object type associates a set of commands that process that type. Membership within the "object class" is more discretionary. A class is a category to which objects are assigned or defined.

Categorizing an object as an object type or object class is
It is not just a semantic execution, but the basis for the basic organization of data in a computer. Object types and classes reside in a particular object hierarchy in a data processing system. System level and program level objects are located at the top of the hierarchy. User-oriented objects, such as word processing documents, exist in an intermediate or lower level hierarchy. Thus an object depends on other objects in the chain that link between levels.

In the prior art, attribute values are propagated down the chain. Returning to the word processing text example, at the opening of the word processing text file, certain default attribute values are automatically formed by the parent object word processing program. This is the traditional approach to dealing with object attribute values, where these attributes are inherited by the object's sub-objects. This method of propagating object values is limited to one-way inheritance, ie inheritance down the object hierarchy. This method cannot propagate attribute values between objects of the same object type. Further, in the conventional method, it is also impossible to propagate attributes between objects of an arbitrary common category.

[0006]

An object of the present invention is to provide a method for extending the propagation of object attribute values between objects in a data processing system.

An object of the present invention is to provide a method for extending access to object type attribute values at a particular level in a data hierarchy.

It is an object of the present invention to provide a method for defining a propagation group for a particular object attribute value without being subject to object rank or predefined interrelationship restrictions between objects.

[0009]

The present invention, upon user initiation, displays the object attribute values of objects higher in rank than the current object in the data hierarchy.

The present invention also displays the object attribute values of objects lower than the current object in the data hierarchy upon user initiation.
That is, changes in object attribute values are propagated both above and below the data hierarchy upon user initiation.

The present invention provides user control over the scope of attribute value changes. In other words, upon user initiation, object attribute values are propagated among all objects of the same class or type in the system. It is also possible to define classes.

The above objective is accomplished by a method and apparatus according to the present invention for propagating object attribute values between objects in a data processing system. Identification of the target object within the object hierarchy is performed in response to user selection. The previous attribute value of the target object is then displayed on the display device. A new object attribute value is created for the target object upon user selection. A propagation group corresponding to the new object attribute value is generated according to the user's specification of the related factor, and the new object attribute value is applied to all the objects in the related group.

The above as well as additional objects, features, and advantages of the present invention will become apparent in the following detailed written description.

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENT Referring to FIG. 1, there is shown the appearance of a personal computer to which the method of the present invention is applied. Personal computer 10 is preferably an IBM Personal System / 2 computer. IBM OS
A / 2 operating system is incorporated into computer system 10. The IBM Presentation Manager Graphic User Interface provides the user with menu selections through windows. The personal computer system 10 includes a microcomputer 12, a keyboard 14, and a display device 16. Mouse 18 is provided as an option
A menu item is selected by locating the mouse pointer on the display screen 20.

FIG. 2 is a diagram representing potential relationships between various data processing system objects and destination objects 28. The dashed separation line 22 indicates the target object 2
Hierarchy of objects 24 including 8 and objects 24
Is a schematic representation of logical separation from objects 26 that are not included in the hierarchy. The target object 28 has a parent object 30 and a child object 32. The parent object 30, target object 28, and child object 32 are labeled Level A, Level B, and Level C, respectively, in the hierarchy. Two-way arrows between the objects 28 and 30 and the objects 32 and 28 indicate directions in which the object attribute value can be propagated.

Object attribute values are also propagated across the partition 22 from the destination object 28 to objects outside the hierarchy 24. The propagation effective range of the object attribute value from the target object 28 is according to the user selection. Objects 26 include objects 34A-34C, which are of the same object type as destination object 28, and also parent object 36A-parent-child object 36C through object 34.
Includes A-Object 34C. Parent object 36A
-The parent-child objects 36C are different types. An example of an object type that has different types of parent objects is a word processing document, which is a spreadsheet program, a database
Affected by access and control through programs or word processing programs. In other words, when the parent object 36A is a word processing program, the parent object 36B is the database manager and the parent object 36C is the spread sheet manager. The respective sub-objects 34A-34C are all word processing documents.

Object 38A-Object 38C
Is the same type as the parent object 30. However, they do exist outside the hierarchy 24 of the destination object 28. The object attribute values applied to the destination object 28 are from object 28 to object 3
8A-propagated to object 38C or received from object 38A-object 38C.

FIG. 3 shows a computer display screen 40,
Here, three windows 42, 44 and 46 are displayed. As will be appreciated by those familiar with multi-tasking computer applications, each window represents a single application program such as, for example, a spreadsheet program, word processing application, or graphics application. Windows 42, 44, and 46 are displayed in an overlapping sequence, which depends on the order in which the applications are opened. Here window 42 is opened first, then window 44, and finally window 46. The mouse pointer 41 is repositioned on the display screen image 40 to select and deselect applications or to select from the menu bar of each window 42, window 44 and window 46. Window 42, window 44 and window 46 include display fields,
In the figure, the display field 48 of the document window 46 is shown. The display field 48 of the document window 46 is entered to manipulate the content or data of the object mapped to the display window 48. As shown, this data represents a text string 49.

FIG. 4 shows a computer display screen 40,
Here, the text object containing the word "document window" is highlighted in box 50. The contents of box 50 becomes the destination object, the data in it represents words, and its attributes include font, font size, background color, and highlighting among other attributes. The values corresponding to the attributes in the example document are inherited.
The values for these attributes can be changed.

FIG. 5 shows a display screen image 40, in which an attribute window 52 is opened corresponding to the target object 50, which is "document exampl" in the identification bar.
Identified by the name "e". Attribute values corresponding to font, type size and emphasis can be changed respectively through input field 56, input field 58 and input field 60. Propagation of attribute value changes Default scope Is shown in display field 62. Propagation of attribute value changes is controlled by accessing the appropriate item from push button 64.

FIG. 6 shows the display screen image 40 that is changed as a result of opening the effective range window 66 by selecting the effective range (Scope) item from the push button 64 of FIG. The coverage window 66 includes a propagation coverage selection field 68. Attribute window 52
The selection of the document to which the change of the object attribute value performed through
It is formed through the selection field 68.

FIG. 7 illustrates an ascending propagation window 70.
Shows the display screen image 40 opened. The ascending propagation window 70 is associated with selecting a propagation scope up the hierarchy of objects. In this example, child object document window 50 has a parent object within document window 48. The document window 48 is open on the chart window 46, and the chart window 46 is open in the spreadsheet window 44. In this example, the hierarchical object chain for the objects in the spread sheet window 44 corresponds to the parent object above it in the chain, with the object in the chart window 46 as the immediate child object and as the grandchild object. It has objects opened through the document window 48. The propagation effective range can be selected through the propagation selection field 72. Push buttons 74 are useful for controlling operations accessible through window 70.

FIG. 8 illustrates a display screen image 40 in which various object attribute values are selected through selection field 56, selection field 58 and selection field 60. The propagation effective range is shown in the display field 62. For example, “all windows” means an object opened in the screen image 40. FIG. 5 in FIG.
Changes from "standard" to "thi for font values
n "and" 10 "to" 8 "for font size values.

FIG. 9 shows the result of applying object attribute values across the effective range shown in FIG. Window 4
2, the headers for windows 44 and 46 are also text, and the propagation scope is window 42.
The choice of font and font size to include the object represented by -46 applies to the header as well as the object opened in the respective display field.

Referring to FIGS. 10-18, there are shown logic flow diagrams representing the method of the present invention. The process begins at block 80 and powers up the computer 12.
Personal computer system 10 is block 8
2. Load various application programs initialized at 2 and potentially used for manipulating data objects within the operating system and data processing system 10. Next, at step 84, the data processing system waits for a user action for changing the object attribute value in the propagateable scope. Next, decision block 86 determines if a destination object has been identified. Once the destination object has been identified, at block 88 the destination object is highlighted in the display image. Next, at decision block 90, it is determined whether the user has requested display of object attribute values. If the user request is received, processing continues at block 92.
This shifts to the attribute operation subroutine. If display of object attribute values is not required, decision block 9
At 4, it is determined whether the user has selected another action for the object attribute value. When the user selects another action, the processing shifts to the letter A of the attribute operation subroutine described later. If no other object attribute value operation is selected, the detected user input is considered another operation for performing the performance on the computer. The computer response to such a request is shown at block 98, from which processing returns to block 84 to await the next user request.

FIG. 11 is an attribute manipulation subroutine that begins at block 92 and also starts with the letter A at block 11.
Entered in 2. Blocks 100-110 relate to displaying the object attribute values of the target object. First, an attribute window frame is generated at block 100. Next, at block 102, information associated with the object is formatted for display in a pre-view window. Next, at block 104, the attributes of the target object are retrieved from memory. Then block 10
At 6, the information is formatted for display in the attribute window frame. Next, at block 108, the window image data is transferred to the display buffer for the display device, and at block 110 this window image data is used to update the display actually seen by the user.

Next, at block 112, monitoring of certain user inputs related to changing object attribute values occurs. Next, at block 114, the user input is "reset."
(RESET) It is determined whether the action is selected. If the result is affirmative, processing transfers to the “reset” routine through block 116. If the result is negative, the process moves to block 118, where the user selects "scope".
(SCOPE) It is determined whether the action is selected. If the scope action is selected, processing continues at block 12.
Through 0, the scope routine is entered. If not, the process then moves to decision block 122 where it is determined if the user has selected the "ASCEND" action associated with ascending propagation of object attribute values in the hierarchical chain. If the result is positive, processing continues at block 12.
Move to ascending order subroutine through 4, and if not,
Go to next decision block 126. At block 126, the process determines whether a "descending" (DESCEND) action has been selected. If the descending action is selected, processing transfers to the descending subroutine at block 128. If the descending action is not selected, processing then proceeds to decision block 1
Moving to step 30, it is judged whether a change of the object attribute value has been requested. If the "CHANGE" action has been selected, processing transfers to the change routine at block 132. Once the modify action is selected, processing then moves to decision block 134, where it is determined if the "APPLY" action has been selected. If the apply action has been selected, processing transfers to the apply routine at block 136. If the apply action is not selected, processing then moves to block 138, where it is determined if the user has selected the "CLOSE" action from the menu. If the close action is selected, processing transfers to block 140. If the close action was not selected, then processing returns to block 112 to monitor another user input, in which case the user has apparently selected an unavailable item.

FIG. 12 shows a flow chart of the object attribute value change routine. The process begins at block 132 and proceeds to block 144 where the current object attribute value is stored in the previous attribute table in memory. Next, at block 146, the newly entered object attribute value is entered into the current attribute table. Next, in operation block 148, the target object is updated to reflect the new object attribute value.
Next, at block 150, the pre-view window is updated to reflect the changed object attribute value.
Next, at block 152, the display buffer is updated with the new object attribute values and the updated pre-display window. Next, at block 156, the display image itself is updated to reflect the change in the object attribute value. From block 156, processing returns to block 84 in the main routine of FIG.

FIG. 13 is a logic flow diagram of the close routine 140. The close routine provides for closing the attribute window. From block 140, processing transfers to block 160, where the display buffer is updated to remove the attribute window. Next, at block 162,
The display itself is updated to clear the attributes window, returning the process to the objects that reside at the bottom of the screen. Processing returns to block 84.

FIG. 14 represents an apply routine, which relates to applying the propagation scope of a set of object attribute values. The process begins at block 134 and proceeds to block 166, where a table of current object attribute values is retrieved. Next, at block 168, the object scope table is retrieved. Next, at operation block 170, the layer object table is retrieved. Next, in operation block 172, the target object is updated to reflect the attributes from the current object attribute value table. Then block 17
4 is performed and the scope and tier are updated to reflect the same current object attribute value. Then, operation block 176 and operation block 1
At 78, a display is generated that reflects the changes made at blocks 166-174. Processing then proceeds to block 8
Return to block 84 through the return step of 1.

FIG. 15 represents the logic flow diagram associated with the reset routine 116, which is used to restore the state of the attribute value one previous change to the object. Following block 116, block 182 is executed to retrieve the object attribute value from the old attribute table. Next, at operation block 184, the previous object attribute value is read into the current attribute table. Next, at decision block 186, it is determined if the user wants to propagate the old attribute through the set of other objects. If no scope or layer changes are required, the operation then proceeds to blocks 194 and 19
Proceed to 2 and the display to the user is updated. When scope or layer changes are indicated, these changes are implemented by processing blocks 188 and 190, the former updating the scope or layer objects to reflect the changes in the current attribute table. , The latter updates the display of all display objects. Operation returns to monitor block 84 by return block 81.

FIG. 16 is a logic flow diagram of the scope routine 120 for defining propagation groups. Processing begins at block 120 and proceeds to block 198 where the propagation coverage window frame is retrieved from memory. Next, at block 200, the object table is accessed to identify the destination object as the source for the object attribute value. Next, in operation block 202, the scope parameter for the target object is retrieved. Next, at operation block 204, the coverage parameters are formatted for display in the coverage window frame. Then operation block 206
At, the default scope parameters are highlighted, and at block 208 and block 210, the display is updated to reflect the scope window and default scope selection.

At this point, the user decides whether or not to change the propagation effective range of the object attribute value. Therefore, the routine next determines at block 212 whether the user has selected to change the scope. Upon selection of a new effective range, these parameters are highlighted at block 214 and block 216 determines if the user wishes to exit this routine. If the change scope is not selected, the process moves directly to block 216 to determine if the user has chosen to exit the routine. Processing returns to decision block 212 via block 218 and continues to monitor user input until the user exits the routine. When you exit the routine,
Operation is block 8 through return block 81
Return to 4.

FIG. 17 is a logic flow diagram for ascending order of object attribute values in a hierarchical chain. Processing of the ascending order routine begins at block 124. The object table is then accessed in operation block 222 to identify the target object.
Next, at block 224, the parent object for the destination object is retrieved from memory. Then block 2
At 26, the layer window frame corresponding to the parent object layer is retrieved. Next, at block 228, the layer window frame is associated with the name of the parent object of the destination object. Next, at blocks 230 and 232, the display image is updated to reflect the search for the layer associated with the parent object. Next, at block 234, the computer waits for more user input.
Next, at block 236, the layer window frame is updated to reflect the user selection or deselection that occurred at block 234. Next, at block 238, the user can decide whether to accept the selection or deselection. If the changes are rejected, the process moves to block 240, the window is closed and the changes are discarded. The process then moves to the return block 81. If the changes are accepted, the process returns directly to block 84.

FIG. 18 is a logic flow diagram of a descending routine 128 for descending object attribute value propagation from a target object in a hierarchical chain. Beginning at block 128, at block 244 the object table is accessed to identify the target object. Next, at block 146, the child object layer corresponding to the destination object is retrieved. Then block 24
At 8, the layer window frame for displaying the object attribute values is retrieved. Next, at block 250,
The layer window frame is updated with the name of the child object. Next, at block 252, the display buffer is updated with the current layer window. Then block 25
At 4, the layer window is displayed. Then block 256
Then, the computer waits for user input related to the propagation of object attribute values. At block 258, the layer window is updated to reflect the user selection or deselection entered at block 256. Next, at decision block 260, the user can decide whether to accept or reject the change. If no changes are selected, block 262.
Closes the window and discards your changes. Upon exiting block 262, both paths from block 260 are merged again and processing is returned via return block 81.
Return to block 84.

[0036]

As described above, according to the present invention,
Propagation of object attribute values between objects in a data processing system is extended.

[Brief description of drawings]

FIG. 1 is a personal computer embodying the present invention.
It is an external view of a system.

FIG. 2 is a diagram schematically showing a valid propagation range of an object attribute value.

FIG. 3 is a diagram showing a plurality of windows in a computer display screen. (Since the display screen of this embodiment is in English, it is shown as it is.)

FIG. 4 is a diagram showing a plurality of windows in the computer display screen of FIG. 1 after identification of a target object. (Since the display screen of this embodiment is in English, it is shown as it is.)

FIG. 5 is a diagram showing a plurality of windows in a computer display screen after displaying object attribute values corresponding to the target object in FIG. (Since the display screen of this embodiment is in English, it is shown as it is.)

FIG. 6 is a diagram showing a plurality of windows in a computer display screen after selecting an object attribute value effective range of a propagation option. (Since the display screen of this embodiment is in English, it is shown as is.)

FIG. 7 is a diagram showing a plurality of windows in a computer display screen after selecting a hierarchy propagation option.
(Since the display screen of this embodiment is in English, it is shown as it is.)

FIG. 8 is a diagram showing a plurality of windows in a computer display screen showing selection of new object attribute values and propagation effective ranges corresponding to those values. (Since the display screen of this embodiment is in English, it is shown as it is.)

FIG. 9 is a diagram showing a plurality of windows after a new object attribute value is selected. (Since the display screen of this embodiment is in English, it is shown as it is.)

FIG. 10 is a logic flow diagram for the method of the present invention.

FIG. 11 is a logic flow diagram for the method of the present invention.

FIG. 12 is a logic flow diagram for the method of the present invention.

FIG. 13 is a logic flow diagram for the method of the present invention.

FIG. 14 is a logic flow diagram for the method of the present invention.

FIG. 15 is a logic flow diagram for the method of the present invention.

FIG. 16 is a logic flow diagram for the method of the present invention.

FIG. 17 is a logic flow diagram for the method of the present invention.

FIG. 18 is a logic flow diagram for the method of the present invention.

Claims (9)

[Claims] 1. A method, performed by a data processing system for propagating object attribute values between object groups, for identifying a target object according to a user selection, generating an attribute value corresponding to said target object, Identifying the propagation group of related objects and applying the new attribute value to the related object group according to a user specification of a factor. 2. The method according to claim 1, wherein in the step of generating the attribute value, the previous attribute value of the target object is displayed, and a new attribute value of the target object is generated according to a user selection. 3. The method according to claim 2, wherein the object attribute value is displayed in an object hierarchy including a target object in response to a user's start. 4. A data processing system for propagating object attribute values between object groups, means for identifying a target object according to user selection, means for generating an attribute value corresponding to the target object, and a related factor. A data processing system comprising: means for identifying a propagation group of a related object according to the user's designation; and means for applying the new attribute value to the related object group. 5. The generating means comprises means for displaying the previous attribute value of the target object and means for generating a new attribute value of the target object in response to user selection. The described data processing system. 6. The data processing system according to claim 5, further comprising means for displaying an object attribute value in an object hierarchy including a target object in response to a user's start. 7. A data processing program product for propagating object attribute values between object groups,
An instruction means for identifying a target object according to a user's selection, including a storage medium; an instruction means for generating an attribute value corresponding to the target object; A data processing program product comprising: instruction means for identifying a propagation group; and instruction means for applying the new attribute value to a related object group. 8. The command means for generating an attribute value, a command means for displaying a previous attribute value of the target object on a display device, a means for generating a new attribute value of the target object on the display device, and a user. 8. The data processing program product according to claim 7, further comprising a command means for generating a new attribute value for the target object in accordance with the selection. 9. The data processing program product according to claim 7, further comprising an instruction unit for displaying an object attribute value in an object hierarchy including a target object according to a user selection.